Direct acting pressure reducing valve

ABSTRACT

A direct acting pressure reducing valve includes a valve-inlet pressure introduction port; a valve-outlet pressure output port; a main valve for opening and closing a communicating conduit; a pilot pressure chamber formed with a flexible diaphragm member; a communicating hole; a connecting rod inserted in the communicating hole; and a biasing member for biasing the flexible diaphragm member in a direction to open the main valve. An insertion portion of the connecting rod has a partly-deformed circular cross section, a distance from a deformed portion thereof to a center of an imaginary circle corresponding to the communicating hole being shorter than a radius of the imaginary circle. A non-deformed portion of the partly-deformed circular cross section guides the connecting rod along the communicating hole, while the deformed portion serves as an air passage via which the communicating conduit and the pilot pressure chamber are communicatively connected.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a direct acting pressure reducingvalve.

2. Description of the Related Art

A direct acting pressure reducing valve is known in the art. The valveincludes a main valve which is disposed in a communicating conduit viawhich a valve-inlet pressure introduction port and a valve-outletpressure output port are communicatively connected with each other. Thevalve-outlet pressure output port is communicatively connected with apilot pressure chamber which is formed by a diaphragm (flexiblediaphragm member). The pilot pressure chamber and the valve-inletpressure introduction port are communicatively connected with each othervia a circular communicating hole, in which a connecting rod is insertedto be freely movable in a sliding manner. The connecting rod is disposedbetween the diaphragm and the main valve, and the pressure in the pilotpressure chamber acts on the diaphragm to be equilibrium with the springforce of a pressure regulating spring and controls the valve-outletpressure by movement of the connecting rod in response to movement ofthe diaphragm. The connecting rod acts on the main valve to move themain valve in a valve closing direction thereof when the pressure in thepilot pressure chamber exceeds the spring force of the pressureregulating spring, while the connecting rod moves down in a direction toopen the main valve so that the pressure which is determined with thepressure regulating spring is output from the valve-outlet pressureoutput port.

In this conventional direct acting pressure reducing valve, it isdesirable that the direct acting pressure reducing valve operatessensitively to vary a cross-sectional area of the main valve so that thepressure in the pilot pressure chamber and the spring force of thepressure regulating spring are balanced. It is known experientially thatthe size of the circular communicating hole, via which the pilotpressure chamber and the valve-inlet pressure introduction port arecommunicatively connected with each other, has a very large influence onthe responsivity to variations of the flow rate on the valve-outletside. The circular communicating hole, via which the pilot pressurechamber and the valve-inlet pressure introduction port arecommunicatively connected with each other, and the connecting rod, whichis inserted in the circular communicating hole to be freely slidably Lmovable therein, are constructed so that the connecting rod can slidablymove in the circular communicating hole normally with a minimumclearance therebetween. In this type of pressure reducing valve, thepressure responsivity of the valve-outlet pressure tends to be delayedin response to a sudden variation of the valve-inlet pressure. It isknown that the valve-outlet pressure overshoots especially when apressure supply valve on the valve-inlet side is opened.

SUMMARY OF THE INVENTION

The present invention provides a direct acting pressure reducing valvewhose pressure characteristics and flow rate characteristics are wellbalanced without any complicated internal structures or any extra parts.

According to an aspect of the present invention, a direct actingpressure reducing valve is provided, including a valve-inlet pressureintroduction port, a valve-outlet pressure output port; a main valve foropening and closing a communicating conduit via which the valve-inletpressure introduction port and the valve-outlet pressure output port arecommunicatively connected with each other, a pilot pressure chamberformed with a flexible diaphragm member to be communicatively connectedwith the valve-outlet pressure output port, a cylindrical communicatinghole via which the pilot pressure chamber and the communicating conduitare communicatively connected with each other, a connecting rod insertedin the cylindrical communicating hole to be slidably movable therein andpositioned between the flexible diaphragm member and the main valve, anda pressure-adjusting biasing member for biasing the flexible diaphragmmember in a direction to open the main valve. An insertion portion ofthe connecting rod which is inserted in the cylindrical communicatinghole is shaped to have a partly-deformed circular cross section, adistance from a deformed portion of the partly-deformed circular crosssection to a center of an imaginary circle corresponding to an innerperipheral surface of the cylindrical communicating hole being shorterthan a radius of the imaginary circle. A non-deformed portion of thepartly-deformed circular cross section of the insertion portion servesas a guide portion for guiding the connecting rod along an axis of thecylindrical communicating hole, while the deformed portion of thepartly-deformed circular cross section of the insertion portion servesas an air passage via which the communicating conduit and the pilotpressure chamber are communicatively connected with each other.

It is desirable for the shape of the insertion portion to constitute amajor portion of an imaginary cylindrical rod, and wherein the deformedportion of the insertion portion of the connecting rod includes a flatportion which defines a cut-off portion of the imaginary cylindricalrod, the flat portion extending in an axial direction of the imaginarycylindrical rod.

It is desirable for the connecting rod to include a flange portionprovided at an end of the connecting rod in the pilot pressure chamber.A surface of the flange portion adjacent to the cylindricalcommunicating hole includes a recessed portion communicatively connectedwith the deformed portion of the insertion portion of the connectingrod.

It is desirable for the direct acting pressure reducing valve to includea body and a bonnet, wherein an outer edge of the flexible diaphragmmember is held tight between the body and the bonnet. The body caninclude the valve-inlet pressure introduction port, the valve-outletpressure output port, and a communicating conduit via which thevalve-inlet pressure introduction port and the valve-outlet pressureoutput port are communicatively connected with each other.

It is desirable for the cylindrical communicating hole to be formed on abushing which is screwed into the communicating conduit.

It is desirable for the pressure-adjusting biasing member to be acompression coil spring positioned in the bonnet.

It is desirable for the connecting rod to include a pushing portionpositioned at the other end of the connecting rod, and for the directacting pressure reducing valve to include a biasing member for biasingthe main valve against an end of the pushing portion.

In another embodiment of the present invention, a direct acting pressurereducing valve is provided, including a valve-inlet pressureintroduction port, a valve-outlet pressure output port, a main valve foropening and closing a communicating conduit via which the valve-inletpressure introduction port and the valve-outlet pressure output port arecommunicatively connected with each other, a pilot pressure chamberformed with a flexible diaphragm member to be communicatively connectedwith the valve-outlet pressure output port, a cylindrical communicatinghole via which the pilot pressure chamber and the communicating conduitare communicatively connected with each other, a connecting rod insertedin the cylindrical communicating hole to be slidably movable therein andpositioned between the flexible diaphragm member and the main valve, anda pressure-adjusting biasing member for biasing the flexible diaphragmmember in a direction to open the main valve. The direct acting pressurereducing valve operates so that a pressure in the pilot pressure chamberacts on the flexible diaphragm member to be in equilibrium with abiasing force of the pressure-adjusting biasing member. A portion of aninner peripheral surface of the cylindrical communicating hole isrecessed radially outwards to serve as an air passage which is elongatedin an axial direction of the cylindrical communicating hole, thecommunicating conduit and the pilot pressure chamber beingcommunicatively connected with each other via the air passage.

It is desirable for the direct acting pressure reducing valve to includea body and a bonnet, wherein an outer edge of the flexible diaphragmmember is held tight between the body and the bonnet. The body caninclude the valve-inlet pressure introduction port, the valve-outletpressure output port, and a communicating conduit via which thevalve-inlet pressure introduction port and the valve-outlet pressureoutput port are communicatively connected with each other.

It is desirable for the cylindrical communicating hole to be formed on abushing which is screwed into the communicating conduit.

It is desirable for the pressure-adjusting biasing member to be acompression coil spring positioned in the bonnet.

Providing either the connecting rod or the cylindrical communicatinghole with an air passage via which the communicating conduit and thepilot pressure chamber are communicatively connected with each othermakes it possible to achieve a direct acting pressure reducing valvewhose pressure characteristics and flow rate characteristics are wellbalanced. A cross-sectional area of the air passage can be determined bytrial and error.

The present disclosure relates to subject matter contained in JapanesePatent Application No. 2003-067722 (filed on Mar. 13, 2003) which isexpressly incorporated herein by reference in its entirety.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be described below in detail with referenceto the accompanying drawings in which:

FIG. 1 is an exploded perspective view of an embodiment of a directacting pressure reducing valve according to the present invention;

FIG. 2 is a longitudinal cross sectional view of a portion of the directacting pressure reducing valve in an assembled state, showing avalve-opened state;

FIG. 3 is a view similar to that of FIG. 2, showing a valve-closedstate;

FIG. 4A is a perspective view of an embodiment of a connecting rod shownin FIG. 1;

FIG. 4B is a front elevational view of the connecting rod shown in FIG.4A;

FIG. 4C is a plan view of the connecting rod shown in FIG. 4A;

FIG. 5A is a perspective view of another embodiment of the connectingrod shown in FIG. 1;

FIG. 5B is a front elevational view of the connecting rod shown in FIG.5A;

FIG. 5C is a plan view of the connecting rod shown in FIG. 5A;

FIG. 6A is a plan view of an embodiment of a bushing shown in FIG. 1;

FIG. 6B is a cross sectional view taken along X-X line shown in FIG. 6A;

FIG. 6C is a plan view of another embodiment of the bushing shown inFIG. 1; and

FIG. 6D is a cross sectional view taken along Y-Y line shown in FIG. 6C.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 shows an overall structure of an embodiment of a direct actingpressure reducing valve according to the present invention. The directacting pressure reducing valve 10 is provided with a body 11 and abonnet 12 which have a cylindrical shape viewed as a whole. The directacting pressure reducing valve 10 is provided between the body 11 andthe bonnet 12 with a diaphragm (flexible diaphragm member) 13 an outeredge of which is held tight between the body 11 and the bonnet 12. Thebody 11 is provided on an end thereof adjacent to the diaphragm 13 witha pilot-pressure-chamber forming recess 14. The body 11 is provided, ata center of the pilot-pressure-chamber forming recess 14 along an axisof the body 11, with a communicating conduit 15 via which a valve-inletpressure introduction port 16 and a valve-outlet pressure output port 17that extend radially in opposite directions are communicativelyconnected with each other. A pilot pressure chamber 19 is formed by thediaphragm 13 and the pilot-pressure-chamber forming recess 14. The pilotpressure chamber 19 and the valve-outlet pressure output port 17 arecommunicatively connected with each other via a communicating throughhole 18.

The communicating conduit 15 consists of a bushing screw hole 15 a, avalve-seat fixing hole 15 b and a spring-insertion bottomed hole 15 c inthat order from the pilot pressure chamber 19. A compression coil spring(main valve spring) 20 is inserted into the spring-insertion bottomedhole 15 c. An annular valve seat 21 made of a resilient material isinserted into the valve-seat fixing hole 15 b to be fixed thereto. Abushing 22 is screwed into the bushing screw hole 15 a to be fixedthereto. A valve body (ball element) 23 serving as a main valve forclosing the communicating conduit 15 by contacting with the annularvalve seat 21 by the spring force of the compression coil spring 20 ispositioned between the compression coil spring 20 and the annular valveseat 21. The compression coil spring 20, the annular valve seat 21 andthe valve body 23 constitute a normally-closed main valve. The annularvalve seat 21 and the bushing 22 can be formed integral with each other.

As shown in FIGS. 2 and 3, the diaphragm 13 is provided on a top surfaceand a bottom surface thereof with a piston 13 a and a retainer plate 13b, respectively, which are coupled to each other by a center guide 13 c.The direct acting pressure reducing valve 10 is provided inside thebonnet 12, which is shaped like an inverted bottomed cylinder to bearthe diaphragm 13 at the bottom thereof, with a pressure adjusting spring(pressure-adjusting biasing member) 25 whose one end (bottom end)contacts with the piston 13 a of the diaphragm 13. The direct actingpressure reducing valve 10 is provided in the bonnet 12 with a springreceiving plate 26 which is positioned on the opposite side of thepressure adjusting spring 25 from the diaphragm 13 to be freely movablein the bonnet 12 in an axial direction thereof. The spring receivingplate 26 is in contact with a end of a pressure-adjustment screw shaft27 which is screwed through a female screw hole formed on a top end wallof the bonnet 12 at a center thereof. The spring force of the pressureadjusting spring 25 which is exerted on the diaphragm 13 can be adjustedby moving the spring receiving plate 26 up and down relative to thebonnet 12 by changing the position of screw-engagement of thepressure-adjustment screw shaft 27.

The bushing 22 is provided on an axis thereof with a cylindricalcommunicating hole 22 a via which the pilot pressure chamber 19 and thecommunicating conduit 15 (i.e., the pilot pressure chamber 19 and thevalve-inlet pressure introduction port 16) are communicatively connectedwith each other. The connecting rod 28 is positioned in thecommunicating hole 22 a to be freely movable therein. The connecting rod28 is provided with a flange portion 28 a, a sliding shaft portion 28 band a pushing portion 28 c. The flange portion 28 a is positioned in thepilot pressure chamber 19 to contact with the center guide 13 c of thediaphragm 13. The sliding shaft portion 28 b is slidably fitted in thecommunicating hole 22 a. An end of the pushing portion 28 c contacts thevalve body 23. It is possible to omit the flange portion 28 a from theconnecting rod 28.

FIGS. 4A, 4B and 4C show external views of an embodiment of theconnecting rod 28. As can be clearly seen from FIGS. 4A through 4C, thesliding shaft portion 28 b is provided with a cylindrical shaft portion28 b 1, and a side flat portion 28 b 2 which is formed in a manner tocut off a portion of the cylindrical shaft portion 28 b 1 in an axialdirection thereof. In other words, a cross sectional shape of thesliding shaft portion 28 b includes a round portion (the cylindricalshaft portion 28 b 1) which constitutes a major portion of an imaginarycircle corresponding to an inner peripheral surface of the communicatinghole 22 a, and a flat portion (the side flat portion 28 b 2) whichdefines a cut-off portion (segment) of the aforementioned imaginarycircle. Namely, an insertion portion (sliding shaft portion 28 b) of theconnecting rod 28 which is inserted in the cylindrical communicatinghole 22 a is shaped to have a partly-deformed circular cross section, adistance from a center of the aforementioned imaginary circle to adeformed portion of the partly-deformed circular cross section beingsmaller than a radius of the imaginary circle. The connecting rod 28 isslidably guided in the communicating hole 22 a in the axial directionthereof by the cylindrical shaft portion 28 b 1, while an air passagevia which the communicating conduit 15 and the pilot pressure chamber 19are communicatively connected with each other is formed in thecommunicating hole 22 a by the side flat portion 28 b 2. The area onwhich the side flat portion 28 b 2 is formed on the sliding shaftportion 28 b and the depth of the side flat portion 28 b 2 arepredetermined so that the cross-sectional area of the aforementioned airpassage is sufficiently large enough without causing any harmful playbetween the connecting rod 28 and the communicating hole 22 a.

The flange portion 28 a serves to prevent the connecting rod 28 fromcoming out of the communicating hole 22 a from the underside thereofadjacent to the valve body 23. In a state shown in FIG. 2 where theflange portion 28 a contacts with the end surface (the upper end surfaceas viewed in FIG. 2) of the bushing 22 which is positioned in the pilotpressure chamber 19, the pushing portion 28 c presses the valve body 23downwards as viewed in FIG. 2 to open the valve (valve-inlet pressureintroduction port 16).

FIGS. 5A, 5B and 5C show external views of another embodiment of theconnecting rod 28. In this embodiment of the connecting rod 28, theaforementioned air passage, via which the communicating conduit 15 andthe pilot pressure chamber 19 are communicatively connected with eachother, remains in an opened state even if the flange portion 28 acontacts the upper end surface of the bushing 22 as shown in FIG. 2. Inthis embodiment shown in FIGS. 5A, 5B and 5C, the flange portion 28 a isprovided, on a bottom surface thereof (i.e., a contacting surface whichis capable of contacting with the upper end surface of the bushing 22)adjacent to the cylindrical communicating hole 22 a, with a flat-cutoutportion (recessed portion) 28 b 3 which is communicatively connectedwith the side flat portion 28 b2.

The direct acting pressure reducing valve 10 that has the abovedescribed structure operates so that the pressure in the pilot pressurechamber 19 acts on the diaphragm 13 to be in equilibrium with the springforce of the pressure adjusting spring 25, and controls across-sectional area of the communicating conduit 15 by movement of theconnecting rod 28 in response to movement of the diaphragm 13 to ensurethe valve-outlet pressure and the flow rate on the valve-outlet side. Inthe case where the flow on the valve-outlet side is shut, the main valveis also shut to keep the valve-outlet pressure constant.

Additionally, in the direct acting pressure reducing valve 10, theconnecting rod 28 is slidably guided with stability by the engagement ofthe cylindrical shaft portion 28 b 1 with an inner peripheral surface ofthe bushing 22 in the communicating hole 22 a, while the air passagebetween the communicating conduit 15 and the pilot pressure chamber 19is secured by the side flat portion 28 b 2 (and the flat-cutout portion28 b 3 in the embodiment shown in FIGS. 5A through 5C). Therefore, asudden variation of the valve-inlet pressure in the valve-inlet pressureintroduction port 16 can be transferred to the pilot pressure chamber 19rapidly, and accordingly, an even more stable valve-outlet pressure canbe output from the valve-outlet pressure output port 17. Specifically,the valve-outlet pressure is prevented from overshooting in thevalve-outlet pressure output port 17 when the valve-inlet pressure inthe valve-inlet pressure introduction port 16 suddenly rises. Inaddition, since no fine adjustment for the diameter of the communicatinghole 22 a and the diameter of the sliding shaft portion 28 b is needed,a direct acting pressure reducing valve which operates with stabilitywithout requiring a lot of skill is achieved.

FIGS. 6A and 6B show another embodiment of the bushing 22, and FIGS. 6Cand 6D show another embodiment of the bushing 22. In each of these twoembodiments shown in FIGS. 6A through 6D, a connecting rod (whichcorresponds to the connecting rod 28) whose cylindrical shaft portion(which corresponds to the cylindrical shaft portion 28 b 1) has no sideflat portion (which corresponds to the side flat portion 28 b 2) is usedinstead of the connecting rod 28 of the previous embodiment shown inFIG. 4A through 4C or 5A through 5C. Accordingly, the cylindrical shaftportion of the connecting rod in each of these two embodiments has acircular cross section. In the embodiment shown in FIGS. 6A and 6B,instead of forming the side flat portion 28 b 2 on the connecting rod28, the bushing 22 is provided in the communicating hole 22 a with around air passage recess 22 b which is recessed radially outwards andelongated in the axial direction of the communicating hole 22 a.Likewise, in the embodiment shown in FIGS. 6C and 6D, the bushing 22 isprovided in the communicating hole 22 a with a square air passage recess22 c which is recessed radially outwards and elongated in the axialdirection of the communicating hole 22 a. Similar effects can beobtained in either embodiment shown in FIGS. 6A through 6D.

According to the present invention, a direct acting pressure reducingvalve having fast response and high stability in a balanced manner isachieved without employing any complicated components.

Obvious changes may be made in the specific embodiments of the presentinvention described herein, such modifications being within the spiritand scope of the invention claimed. It is indicated that all mattercontained herein is illustrative and does not limit the scope of thepresent invention.

1-7. (canceled)
 8. A direct acting pressure reducing valve comprising: avalve-inlet pressure introduction port; a valve-outlet pressure outputport; a main valve for opening and closing a communicating conduit viawhich said valve-inlet pressure introduction port and said valve-outletpressure output port are communicatively connected with each other; apilot pressure chamber formed with a flexible diaphragm member to becommunicatively connected with said valve-outlet pressure output port; acylindrical communicating hole via which said pilot pressure chamber andsaid communicating conduit are communicatively connected with eachother; a connecting rod inserted in said cylindrical communicating holeto be slidably movable therein and positioned between said flexiblediaphragm member and said main valve; and a pressure-adjusting biasingmember for biasing said flexible diaphragm member in a direction to opensaid main valve, wherein said direct acting pressure reducing valveoperates so that a pressure in said pilot pressure chamber acts on saidflexible diaphragm member to be in equilibrium with a biasing force ofsaid pressure-adjusting biasing member, and wherein a portion of aninner peripheral surface of said cylindrical communicating hole isrecessed radially outwards to serve as an air passage which is elongatedin an axial direction of said cylindrical communicating hole, saidcommunicating conduit and said pilot pressure chamber beingcommunicatively connected with each other via said air passage.
 9. Thedirect acting pressure reducing valve according to claim 8, said directacting pressure reducing valve comprising a body and a bonnet, whereinan outer edge of said flexible diaphragm member is held tight betweensaid body and said bonnet, and wherein said body includes saidvalve-inlet pressure introduction port, said valve-outlet pressureoutput port, and a communicating conduit via which said valve-inletpressure introduction port and said valve-outlet pressure output portare communicatively connected with each other.
 10. The direct actingpressure reducing valve according to claim 9, wherein said cylindricalcommunicating hole is formed on a bushing which is screwed into saidcommunicating conduit.
 11. The direct acting pressure reducing valveaccording to claim 9, wherein said pressure-adjusting biasing membercomprises a compression coil spring positioned in said bonnet.